JP4373985B2 - Ozone water generator - Google Patents

Description

  The present invention relates to an ozone water generating device capable of generating warm ozone water suitable for medical care and nursing care.

In recent years, in addition to the spread of food sterilization, ozone water is effective for medical use, especially for treatment of pressure ulcers of bedridden elderly people, burns, and the prevention of the occurrence of atopy and keloid. Many treatment examples have been proposed.
As described above, the method of producing ozone water that is currently widely used for medical and industrial purposes is roughly divided into a gas dissolving method for dissolving in ozone gas generated by discharge, an electrolytic gas dissolving method for dissolving ozone gas generated by electrolysis in water, Three methods of direct electrolysis (for example, refer to Patent Document 1) in which raw water is brought into direct contact with the electrolytic surface to generate ozone water have been put into practical use.
JP-A-8-134678

By the way, in the above-mentioned treatment, it is said that it is desirable to use warm ozone water of 25 ° C. to 30 ° C. in order not to irritate sensitive skin as much as possible.
On the other hand, in the process in which ozone is dissolved in water to become ozone water, the dissolution rate follows the so-called Henry's law, and the dissolution rate is said to be higher as the temperature is lower. Therefore, in the semiconductor processing field that currently uses a lot of ozone water, there are many examples that use high-concentration ozone water at a low temperature of 5 to 10 ° C. Therefore, when producing warm ozone water suitable for medical use, it is produced at a high temperature, and when produced at a high temperature, the dissolution rate is lower than that produced at a low temperature, and the production efficiency of ozone water is low. It was bad.
Then, this invention was made | formed in view of the said situation, and it aims at providing the ozone water production | generation apparatus which can produce | generate the high concentration warm ozone water easily and efficiently.

In the direct electrolysis method in which the anode electrode and the cathode electrode are pressed into contact with both sides of the cation exchange membrane and water is brought into contact with the anode electrode to generate ozone water, the present inventors generate oxygen water and ozone at the anode electrode. Hydrogen is generated at the cathode electrode, but since the anode electrode is in contact with water, Joule heat generated during energization is cooled, but the cathode electrode is usually not in contact with water, so it is generated at the cathode electrode. It was found that the Joule heat was not dissipated, which led to the temperature rise of the catalyst electrode and reduced the generation efficiency of ozone water.
The present invention utilizes these phenomena, uses Joule heat generated at the cathode electrode to raise the temperature of the raw material water, and at the same time leads to cooling of the cathode electrode, so that warm ozone water can be obtained more easily and energy saving. It was.
In order to solve the above problem, the invention of claim 1 includes, for example, as shown in FIGS. 1 and 2, a water tank 1 filled with raw water, and a catalyst electrode 2 disposed in the water tank,
The catalyst electrode has a cylindrical shape in which a cation exchange membrane 21 is wound around an outer peripheral surface of a cylindrical cathode electrode 23, and further, an anode electrode 22 is wound around an outer peripheral surface of the cation exchange membrane. Formed,
In the ozone water generating apparatus 100 that generates ozone water by applying a DC voltage between the anode electrode and the cathode electrode,
A heat conductor 3 having high thermal conductivity that comes into contact with the raw water in the water tank is provided in contact with the cathode electrode, and the Joule heat generated at the cathode electrode is guided to the water through the heat conductor. It is characterized by obtaining ozone water .

According to the invention of claim 1, the catalyst electrode is provided in the order of the cathode electrode, the cation exchange membrane, and the anode electrode in this order from the inside, and the heat conductor having high thermal conductivity that contacts the cathode electrode in water. Since Joule heat generated at the cathode electrode is not radiated from the anode electrode to the water via the cation exchange membrane, it is immediately introduced into the water via the heat conductor and radiated. . Thus, the temperature of ozone water can be raised by dissipating heat into the water, and warm ozone water can be easily generated using heat dissipation without raising the temperature of ozone water by another means. . Further, since the cathode electrode can dissipate heat, the ozone generation efficiency can be increased, and high-concentration ozone water can be obtained.
Furthermore, since the cathode electrode is arranged on the inner side of the anode electrode, there is little contact with the raw material water, hydrogen generated in the cathode electrode by energization can be prevented from mixing with ozone water in the water tank, and hydrogen However, hydrogen ionization having a strong reducing action in water does not occur, and the catalytic action of the cathode electrode can be reduced by this reducing action. As a result, a good catalytic function of the cathode electrode can be maintained, and stable generation of ozone water can be continued.

The invention of claim 2 is an ozone water generator according to claim 1, for example, as shown in FIGS.
The heat conductor includes a rod-like base portion 31 extending downward from a cylindrical lower end portion of the cathode electrode, and a plurality of fins 32 arranged vertically at predetermined intervals so as to intersect the base portion. The heat sink 3 is provided with 32,.

  According to the invention of claim 2, the heat conductor includes a rod-like base portion extending downward from the cylindrical lower end portion of the cathode electrode and a plurality of fins arranged so as to intersect the base portion. Since the heat sink is provided, the structure is simple and the heat dissipation structure can be easily obtained.

The invention of claim 3 includes, for example, as shown in FIG. 3, a water tank 1A filled with raw water and a catalyst electrode 2A disposed in the water tank,
The catalyst electrode is formed in a flat plate shape in which the anode electrode 22A is pressed against one surface of the cation exchange membrane 21A and the cathode electrode 23A is pressed against the other surface.
In the ozone water generating apparatus 100A that generates ozone water by applying a DC voltage between the anode electrode and the cathode electrode,
A surface of the cathode electrode opposite to the contact surface with the cation exchange membrane is provided in contact with a heat conductor 3A having high thermal conductivity in contact with the raw water in a water tank, and the Joule generated at the cathode electrode Warm ozone water is obtained by conducting heat into the water through the heat conductor.

According to the invention of claim 3, the catalyst electrode is formed in a flat plate shape in which the anode electrode is pressed against one surface of the cation exchange membrane and the cathode electrode is pressed against the other surface. A heat conductor with high thermal conductivity in contact with water is in contact with the surface opposite to the contact surface with the cation exchange membrane, so Joule heat generated at the cathode electrode enters the water through the heat conductor. It is guided and dissipated. Thus, the temperature of ozone water can be raised by dissipating heat into the water, and warm ozone water can be easily generated using heat dissipation without raising the temperature of ozone water by another means. . Further, since the cathode electrode can dissipate heat, the ozone generation efficiency can be increased, and high-concentration ozone water can be obtained.
Furthermore, since the heat conductor is provided in contact with the surface opposite to the contact surface of the cathode electrode with the cation exchange membrane, the contact area of the cathode electrode with the raw material water is reduced. That is, if the cathode electrode is immersed in water, the generated hydrogen ionizes into hydrogen ion having a strong reducing action in water, reducing the cathode electrode to reduce the catalytic action, but the contact area with the raw water is small Therefore, a good catalytic function of the cathode electrode can be maintained, and stable generation of ozone water can be continued.

The invention of claim 4 is an ozone water generator according to claim 3, for example, as shown in FIG.
The heat conductor includes a plate-like base portion 31A that is in contact with the surface of the cathode electrode that is opposite to the contact surface with the cation exchange membrane, and a predetermined interval up and down so as to intersect the base portion. The heat sink 3A includes a plurality of fins 32A, 32A,... Arranged.

  According to the invention of claim 4, the heat conductor is disposed so as to intersect the base portion and the plate-like base portion that contacts the surface opposite to the contact surface of the cathode electrode with the cation exchange membrane. Since the heat sink includes a plurality of fins, the structure is simple and the heat dissipation structure can be easily obtained.

The invention of claim 5 is, for example, as shown in FIG.
The base portion extends from at least one of an upper end portion and a lower end portion of the cathode electrode, and the fin is arranged on the extended base portion.

According to the invention of claim 5, since the base portion extends from at least one of the upper end portion or the lower end portion of the cathode electrode, and the fin is arranged on the extended base portion, the extended base portion and the base portion thereof With the fins arranged on the heat radiation area, the heat radiation area can be increased, and the heat radiation effect can be further improved.
In addition, when the base portion is extended from at least one of the upper end portion or the lower end portion of the cathode electrode, hydrogen generated from the cathode electrode can be led upward or downward along the base portion to be released. When hydrogen is released upward, mixing of ozone water and hydrogen in the water tank can be prevented, and the efficiency of generating ozone water can be improved.

As for invention of Claim 6, as shown in FIG. 1, FIG. 2, in the ozone water generating apparatus 100 as described in any one of Claims 1-5,
The cathode electrode is a metal coated with silver or silver chloride.

  According to the invention of claim 6, since the cathode electrode is a metal coated with silver or silver chloride having high ion mobility necessary for ozone generation and high thermal conductivity, it is effective for heat dissipation and ozone. The generation efficiency can be improved.

  According to the present invention, Joule heat generated at the cathode electrode can be dissipated into the water via the heat conductor, and this heat dissipation can be utilized for raising the temperature of the ozone water. As a result, warm ozone water with less stimulation suitable for medical use can be easily obtained.

Hereinafter, first and second embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of an ozone water generator 100 according to the first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along the cutting line II-II in FIG.
As shown in FIGS. 1 and 2, the ozone water generating apparatus 100 is configured by arranging a catalyst electrode 2 in a water tank 1 filled with raw water (for example, water), and a direct current voltage is applied to the catalyst electrode 2. Is a device that generates ozone water by generating ozone bubbles and dissolving the ozone bubbles in raw water.
The water tank 1 has a cylindrical shape with an open upper end, and the water tank 1 is filled with raw material water up to the vicinity of the upper end portion. A catalyst electrode 2 is disposed in the water tank 1.

The catalyst electrode 2 includes a cathode electrode 23, a cation exchange membrane 21, and an anode electrode 22 that are wound in a cylindrical shape in order from the inside. That is, the cathode electrode 23 is wound in a cylindrical shape, the cation exchange membrane 21 is wound around the cathode electrode 23 in a cylindrical shape, and the anode electrode 22 is wound around the cation exchange membrane 21 in a cylindrical shape. .
The catalyst electrode 2 formed in such a cylindrical shape is arranged in the water tank 1 so that the longitudinal direction of the cylinder is up and down. The catalyst electrode 2 disposed in the water tank 1 is such that most of the raw material water is in contact with the surface of the anode electrode 22 located on the outermost periphery of the catalyst electrode 2, and the cathode located on the inner periphery of the catalyst electrode 2. The electrode 23 does not contact the raw material water as much as the anode electrode 22.

  As a method for fixing the catalyst electrode 2 in the water tank 1, although not shown, for example, a rod-shaped attachment member is provided at a predetermined position from the inner wall surface of the water tank 1 toward the anode electrode 22 and supported thereby. In addition, it is good also as a structure suspended from the upper direction of the water tank 1. FIG. The mounting member used is preferably made of an ozone resistant material.

  Further, the upper end surfaces of the anode electrode 22 and the cathode electrode 23 are electrically connected to the plus terminal 241 and the minus terminal 242 of the power supply device 24 through conductive wires, respectively. A predetermined voltage is applied between the cathode electrode 23 and the cathode electrode 23. The DC voltage to be applied is preferably 9 to 15 volts (V), for example.

  As the cation exchange membrane 21, a conventionally known one can be used, and a fluorine-based cation exchange membrane having high durability against the generated ozone can be used. For example, a thickness of 100 to 250 microns is preferable.

  The anode electrode 22 is not in close contact with the cation exchange membrane 21 so as to cover the entire surface. The anode electrode 22 is provided with a large number of through holes, and the anode electrode 22 is provided with a contact portion and a non-contact portion on the cation exchange membrane 21. Are stacked. That is, it is preferable that the anode electrode 22 has a grating shape or a punching metal shape. FIG. 2 shows a case where the anode electrode 22 has a grating shape. Specifically, the grating shape is a lattice shape in which wires are welded, and the punching metal shape is a porous plate shape in which a large number of through holes are formed in a metal plate.

As the anode electrode 22, a metal having an ozone generation catalytic function is used, and lead dioxide is most widely known as this metal. However, this lead dioxide is difficult to process and uses a porous body with irregularly small pores, but the lead dioxide porous body is fragile and inferior in durability, and lead elutes into ozone water. Therefore, in order to obtain pure ozone water, it is preferable to use a platinum or platinum-coated metal electrode, and in the present invention, it is particularly preferable to use a metal in which titanium is coated with platinum.
The anode electrode 22 is preferably processed from a planar metal into a grating shape. Moreover, as a coating process, it can carry out by plating, heat deposition, etc., for example.

  By using the grating-like anode electrode 22 in this way, the intersection part of the members constituting the anode electrode 22 is pointed and protrudes to the outer surface to generate a vortex in contact with the water flow. Can be dissolved to accelerate dissolution.

  On the other hand, the cathode electrode 23 is preferably made of silver or a thin silver wire net with a silver chloride coating. In particular, the cathode electrode 23 is formed so as to have a coarser mesh than the anode electrode 22. It is preferable that

In the catalyst electrode 2 as described above, the heat sink 3 is attached to the lower end portion of the cathode electrode 23.
The heat sink 3 includes a rod-shaped base portion 31 extending downward from the lower end portion of the cathode electrode 23 and a plurality of heat sinks 3 arranged at predetermined intervals along the top and bottom of the base portion 31 so as to be substantially perpendicular to the base portion 31. Air cooling fins 32, 32,...
The upper end of the base 31 is inserted and fixed in the cylindrical interior 231 at the lower end of the cathode electrode 23, and supports the plurality of air cooling fins 32, 32,. The base 31 and the air-cooled fins 32, 32,... Diffuse the generated heat into the water using the heat conducted by the base electrode 31 and the air-cooled fins 32, 32,. Functions as a heat sink. In addition, it is preferable that the base part 31 and the air cooling fins 32, 32, ... are formed from aluminum, aluminum alloy, or copper with high thermal conductivity.

  Further, a rotor 81 such as a magnet stirrer is provided on the inner bottom surface of the water tank 1, and a stirring device 82 for stirring the rotor 81 with a magnetic force is provided on the outer bottom surface of the water tank 1. By stirring the rotor 81 with a magnetic force, a swirling water flow can be generated in the water tank 1 and the raw material water can be brought into continuous contact with the anode electrode 22 of the catalyst electrode 2.

Further, a water tank concentration detection sensor (not shown) for detecting the ozone concentration of ozone water generated in the water tank 1 is provided in the water tank 1. The concentration detection sensor in the aquarium is composed of a detection electrode, a reference electrode serving as a reference for potential measurement, a potentiometer that connects the detection electrode and one end of the comparison electrode, and measures a potential. Therefore, the tip part (the other end part) of the detection electrode and the comparison electrode is brought into contact with the ozone water in the water tank 1, and the concentration is measured by detecting the potential difference between the detection electrode and the comparison electrode due to the ozone concentration change of the detection electrode. .
As the detection electrode, for example, an electrode made of platinum or gold is preferably used, and silver / silver chloride is preferably used as the comparison electrode.
Based on the ozone concentration thus detected, the voltage applied between the anode electrode 22 and the cathode electrode 23 is controlled by the power supply device 24 so as to coincide with the preset ozone concentration.

Next, an ozone water generation method using the ozone water generation apparatus 100 having the above-described configuration will be described.
First, a rotating water flow is generated in the water tank 1 by stirring the rotor 81 with the stirring device 82. Here, most of the water flow continuously contacts the surface of the anode electrode 22, and a part of the water flows from the upper end of the catalyst electrode 2 and contacts the surface of the cathode electrode 23. At the same time, the power supply device 24 is driven to apply a predetermined DC voltage between the anode electrode 22 and the cathode electrode 23. By this energization, the raw water in the water tank 1 is electrolyzed, ozone bubbles are generated on the anode electrode 22 side, and hydrogen bubbles are generated on the cathode electrode 23 side.

  Here, on the anode electrode 22 side, the flow direction is complicated due to slight unevenness of the anode electrode 22, resulting in a vortex. Therefore, on the anode electrode 22 side, the generated ozone bubbles are quickly taken into water and dissolved to generate ozone water, and between the anode electrode 22 and the cation exchange membrane 21 (more precisely, the anode electrode 22 and the cathode electrode). 23), a state where a large amount of current flows is ensured.

  On the other hand, hydrogen bubbles are generated vigorously on the cathode electrode 23 side, the cylindrical interior 231 of the cathode electrode 23 is filled with hydrogen bubbles, rises to the water surface, and is discharged out of the system. This can prevent hydrogen from being decomposed by reacting with the generated ozone water. Further, it is desirable that the generated hydrogen is immediately collected and effectively used as fuel for the fuel cell, for example.

  Further, Joule heat is generated in the anode electrode 22 and the cathode electrode 23 by energization. The Joule heat generated in the anode electrode 22 is generated in the water tank 1 because the anode electrode 22 is located on the outermost periphery of the catalyst electrode 2. Heat is immediately released by contact with raw water. On the other hand, Joule heat generated in the cathode electrode 23 is conducted to the air cooling fins 32, 32,... Via the base portion 31 of the heat sink 3 and is dissipated by coming into contact with the raw material water in the water tank 1.

During energization, the concentration of the solution in the water tank 1 is simultaneously measured by the concentration sensor in the water tank, and the power supply device 24 outputs so that the ozone concentration in the water tank 1 becomes a preset ozone concentration. Thus, the voltage between the anode electrode 22 and the cathode electrode 23 is controlled.
As described above, ozone water having a set concentration is generated.

As described above, according to the first embodiment of the present invention, the catalyst electrode 2 is provided in a cylindrical shape by superposing the cathode electrode 23, the cation exchange membrane 21, and the anode electrode 2 in this order from the inside. Since the heat sink 3 having high thermal conductivity contacting the water is joined to the water 23, the Joule heat generated in the cathode electrode 23 is not radiated from the anode electrode 22 to the water via the cation exchange membrane 21, The heat is immediately introduced into the water through the heat sink 3 to be dissipated. Thus, the temperature of ozone water can be raised by radiating heat into water, and warm ozone water can be easily generated using heat radiation. Further, since the cathode electrode 23 can dissipate heat, the ozone generation efficiency can be increased, and high-concentration ozone water can be obtained.
Furthermore, since the cathode electrode 23 is arranged on the inner side of the anode electrode 22, there is little contact with the raw material water, and hydrogen generated in the cathode electrode 23 by energization can be prevented from being mixed with ozone water in the water tank 1. In addition, hydrogen does not become hydrogen ion having a strong reducing action in water, and the reduction of the catalytic action of the cathode electrode 23 by this reducing action can be reduced. As a result, a good catalytic function of the cathode electrode 23 can be maintained, and stable generation of ozone water can be continued.
The heat sink 3 includes a rod-like base portion 31 extending downward from the lower end portion of the cathode electrode 23 and a plurality of fins 32, 32,... Arranged so as to intersect the base portion 31. Therefore, the structure is simple and a heat dissipation structure can be easily obtained.
Furthermore, since the cathode electrode 23 is a metal coated with silver or silver chloride having high ion mobility necessary for ozone generation and high thermal conductivity, it is effective for heat dissipation and improves ozone generation efficiency. Can do.

[Second Embodiment]
FIG. 3 is a longitudinal sectional view of an ozone water generator 100A according to the second embodiment of the present invention.
In the second embodiment, a catalyst electrode 2A having a shape different from that of the catalyst electrode 2 of the first embodiment is used, and the cathode electrode 23A is opposite to the contact surface with the cation exchange membrane 21A. A heat sink 3A is provided on the surface.
The ozone water generating apparatus 100A includes a water tank 1A similar to that in the first embodiment, and a catalyst electrode 2A disposed in the water tank 1A. The catalyst electrode 2A is formed by bringing the anode electrode 22A into close contact with one surface of the cation exchange membrane 21A and the cathode electrode 23A into close contact with the other surface. The catalyst electrode 2A is formed by bonding with an insulating bonding member (not shown).
The catalyst electrode 2A is arranged so that the anode electrode 22A faces the cylindrical central portion of the water tank 1A and the cathode electrode 23A faces the inner wall surface of the water tank 1A.
As a method for fixing the catalyst electrode 2 </ b> A in the water tank 1 </ b> A, a structure in which the catalyst electrode 2 </ b> A is suspended from above the water tank 1 may be used.

  In addition, as in the first embodiment, the positive terminal 241A and the negative terminal 242A of the power supply device 24A are connected between the anode electrode 22A and the cathode electrode 23A via a conductive wire, respectively. A DC voltage is applied by driving. In addition, about the material of the cation exchange membrane 21A, anode electrode 22A, and cathode electrode 23A, the thing similar to 1st Embodiment can be used.

  In the catalyst electrode 2A as described above, the heat sink 3A is attached to the surface of the cathode electrode 23A facing the inner wall surface of the water tank 1A (the surface opposite to the contact surface with the cation exchange membrane 21A). The heat sink 3A has a plate-like base portion 31A extending along the top and bottom on a surface opposite to the contact surface of the cathode electrode 23A with the cation exchange membrane 21A, and substantially perpendicular to the base portion 31A. Are provided with a plurality of air cooling fins 32A, 32A,... The upper and lower ends of the base portion 31A extend upward and downward from the upper and lower ends of the cathode electrode 23A, respectively, and air cooling fins 32A, 32A,... Are attached to the extended base portion 31A. The base portion 31A is fixed to the cathode electrode 32A with a double-sided tape or the like having high thermal conductivity, and the base portion 31A and the air cooling fins 32A, 32A,. Made of copper.

  Further, a rotor 81A is provided on the inner bottom surface of the water tank 1A, and a stirring device 82A is provided on the outer bottom surface. Further, an in-water concentration detection sensor (not shown) for detecting the concentration in the water tank 1A is also provided as in the first embodiment.

Next, an ozone water generating method using the ozone water generating apparatus 100A having the above-described configuration will be described.
First, a rotating water flow is generated in the water tank 1A by stirring the rotor 81A with the stirring device 82A. Here, most of the water flow is in continuous contact with the surface of the anode electrode 21A located at the center of the water tank 1A, and part of it is in contact with the surface of the cathode electrode 23A located on the inner wall surface side of the water tank 1A. At the same time, the power supply device 24A is driven to apply a predetermined DC voltage between the anode electrode 22A and the cathode electrode 23A. By this energization, the raw water in the water tank 1A is electrolyzed, ozone bubbles are generated on the anode electrode 22A side, and hydrogen bubbles are generated on the cathode electrode 23A side.

  Here, on the side of the anode electrode 22A, the flow direction is complicated due to slight unevenness of the anode electrode 22A, resulting in a vortex. Therefore, on the anode electrode 22A side, the generated ozone bubbles are promptly taken into water and dissolved to generate ozone water, and between the anode electrode 22A and the cation exchange membrane 21A (more precisely, the anode electrode 22A and the cathode electrode). 23A), a state where a large amount of current flows is ensured.

  On the other hand, hydrogen bubbles are generated vigorously on the cathode electrode 23A side, are led to the base portion 31A of the heat sink 3A, rises to the water surface, and are discharged out of the system. This can prevent hydrogen from being decomposed by reacting with the generated ozone water. Further, it is desirable that the generated hydrogen is immediately collected and effectively used as fuel for the fuel cell, for example.

  Further, Joule heat is generated in the anode electrode 22A and the cathode electrode 23A by energization, but the Joule heat generated in the anode electrode 22A is immediately radiated by the anode electrode 22A coming into contact with the raw water in the water tank 1A. On the other hand, Joule heat generated in the cathode electrode 23A is conducted to the air cooling fins 32A, 32A,... Via the base portion 31A of the heat sink 3A, and is dissipated by coming into contact with the raw water in the water tank 1A.

During energization, the concentration of the solution in the water tank 1A is simultaneously measured by the concentration sensor in the water tank, and the power supply device 24A outputs so that the ozone concentration in the water tank 1A becomes a preset ozone concentration. Thus, the voltage between the anode electrode 22A and the cathode electrode 23A is controlled.
As described above, ozone water having a set concentration is generated.

As described above, according to the second embodiment of the present invention, the catalyst electrode 2A is a flat plate formed by pressing the anode electrode 22A on one surface of the cation exchange membrane 21A and pressing the cathode electrode 23A on the other surface. Since the heat sink 3A having high thermal conductivity in contact with water is in contact with the surface opposite to the contact surface of the cathode electrode 22A with the cation exchange membrane 21A, it is generated at the cathode electrode 23A. The Joule heat is immediately introduced into the water through the heat sink 3A and radiated. Thus, the temperature of ozone water can be raised by radiating heat into water, and warm ozone water can be easily generated using heat radiation. Moreover, since the cathode electrode 23A can dissipate heat, the ozone generation efficiency can be increased, and high-concentration ozone water can be obtained.
Furthermore, since the heat sink 3A is provided in contact with the surface opposite to the contact surface of the cathode electrode 23A with the cation exchange membrane 21A, the contact area of the cathode electrode 23A with the raw material water is reduced. That is, when the cathode electrode 23A is immersed in water, the generated hydrogen is ionized into hydrogen having a strong reducing action in the water, and the cathode electrode 23A is reduced to reduce the catalytic action. Therefore, a good catalytic function of the cathode electrode 23A can be maintained, and stable generation of ozone water can be continued.
The heat sink 3A has a plate-like base portion 31A that contacts the surface of the cathode electrode 23A opposite to the contact surface with the cation exchange membrane 21A, and a plurality of fins 32A that are arranged so as to intersect the base portion 31A. , 32A,..., So that the structure is simple and a heat dissipation structure can be easily obtained.
Further, since the base portion 3A extends upward and downward from the upper end portion and the lower end portion of the cathode electrode 23A, and the fins 32A are arranged on the extended base portion 31A, the extended base portion 31A and its base portion The heat radiation area can be increased by the fins 32A disposed on 31A, and the heat radiation effect can be further improved. Furthermore, the hydrogen generated from the cathode electrode 23A can be led upward or downward along the base portion 31A and released. By releasing hydrogen upward, it is possible to prevent the ozone water and hydrogen in the water tank 1 </ b> A from being mixed with each other, and the ozone water generation efficiency can be improved.
Moreover, since the cathode electrode 23A is a metal coated with silver or silver chloride that has high ion mobility necessary for ozone generation and has high thermal conductivity, it is effective for heat dissipation and improves ozone generation efficiency. Can do.

In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the summary, it can change suitably.
For example, in the second embodiment, the base portion 31A of the heat sink 3A is plate-shaped so as to come into contact with the surface opposite to the contact surface of the cathode electrode 23A with the cation exchange membrane 21A. A heat conductor may also be provided on the side surface so as to cover the outer surface of the cathode electrode 23A, and the base portion may be formed in a box shape. As a result, the area where the cathode electrode 23A comes into contact with the raw material water is reduced, and the catalytic function of the cathode electrode 23A due to hydrogen ionization can be prevented, and the generated hydrogen reacts with ozone water. Can be prevented.

  In the first and second embodiments, the water tanks 1 and 1A have a cylindrical shape, but may have a rectangular tube shape. Further, the catalyst electrode 2 of the first embodiment is not limited to a cylindrical shape, and may be a rectangular tube shape.

Next, the effect of the ozone water generating device according to the present invention will be described by taking the ozone water generating device 100 of the first embodiment as an example.
[Example]
In a cylindrical cell having an electrode area of about 15 cm ^{2 for} the catalyst electrode 2, a titanium micrograting coated with platinum having a thickness of 2 μm is used as the anode electrode 22, and a DuPont naphth ion membrane is used as a cation exchange membrane. 21 was used, and the cathode electrode 23 used was a silver grating surface coated with silver chloride having a thickness of 0.5 mm. Then, a heat sink 3 made of aluminum having a surface area of about 50 cm ² was connected to the lower end of the cathode electrode 23. In such an ozone water generating device 100, a current of about 10 amperes (A) flows with a direct current of 12 volts (V) and is stirred in about 2 L of the water tank 1, and 4 ppm of ozone water is obtained in about 2 minutes. The water temperature rose from 20 ° C to 26 ° C.
As a comparative example, when the operation was performed with the above cylindrical catalyst electrode without a heat sink, the current decreased to about 8 A, the concentration of ozone water was 2.5 ppm and the water temperature was around 23 ° C. in about 2 minutes. In particular, the difference in the efficiency of ozone water generation proved that the cathode electrode was hot. When the temperature of the cathode electrode was measured, the former (example of the present invention provided with a heat sink) was a water temperature plus 1 to 2 ° C., whereas the latter (comparative example) showed a high water temperature plus 12 to 15 ° C. .
Since dermatological treatment has a temperature of 25 to 30 ° C. that does not irritate the skin, it is recognized that this example can easily generate warm ozone water having a concentration and temperature suitable for treatment. It is done.

It is the perspective view which showed typically the ozone water production | generation apparatus 100 in 1st embodiment of this invention. It is arrow sectional drawing at the time of cut | disconnecting along the cutting line II-II. It is the longitudinal cross-sectional view which showed typically the ozone water production | generation apparatus 100A in 2nd embodiment of this invention.

Explanation of symbols

1, 1A Water tank 2, 2A Catalyst electrode 3, 3A Heat sink (thermal conductor)
21, 21A Cation exchange membrane 22, 22A Anode electrode 23, 23A Cathode electrode 31, 31A Base part 32, 32A Fin 100, 100A Ozone water generator

Claims (6)

A water tank filled with raw water, and a catalyst electrode disposed in the water tank,
The catalyst electrode is formed in a cylindrical shape in which a cation exchange membrane is wound around an outer peripheral surface of a cylindrical cathode electrode, and further, an anode electrode is wound around an outer peripheral surface of the cation exchange membrane,
In the ozone water generating device that generates ozone water by applying a DC voltage between the anode electrode and the cathode electrode,
A thermal conductor having high thermal conductivity that contacts raw material water in the water tank is provided in contact with the cathode electrode, and the Joule heat generated at the cathode electrode is introduced into water through the thermal conductor to warm ozone. An ozone water generator characterized by obtaining water.   The heat conductor includes a rod-like base portion extending downward from a cylindrical lower end portion of the cathode electrode, and a plurality of fins arranged vertically at predetermined intervals so as to intersect the base portion. The ozone water generator according to claim 1, wherein the ozone water generator is a heat sink. A water tank filled with raw water, and a catalyst electrode disposed in the water tank,
The catalyst electrode is formed in a flat plate shape formed by pressing an anode electrode on one surface of a cation exchange membrane and pressing a cathode electrode on the other surface,
In the ozone water generating device that generates ozone water by applying a DC voltage between the anode electrode and the cathode electrode,
A surface of the cathode electrode opposite to the contact surface with the cation exchange membrane is provided in contact with a heat conductor having high thermal conductivity in contact with the raw water in a water tank, and Joule heat generated at the cathode electrode. A warm ozone water is obtained by introducing water into the water through the heat conductor.   The heat conductor is disposed at a predetermined interval vertically so as to intersect the base portion and a plate-like base portion that contacts the surface of the cathode electrode opposite to the contact surface with the cation exchange membrane. The ozone water generating device according to claim 3, wherein the ozone water generating device is a heat sink including a plurality of fins.   The ozone water generating apparatus according to claim 4, wherein the base portion extends from at least one of an upper end portion and a lower end portion of the cathode electrode, and the fin is disposed on the extended base portion. .   The ozone water generating apparatus according to claim 1, wherein the cathode electrode is a metal coated with silver or silver chloride.

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